DE1036627B - Photoelectric exposure control device for photographic copiers - Google Patents

Description

The invention relates to a photoelectric exposure control device for photographic copiers which, depending on the average negative density, perform the copying process controls.

It is already known, in devices of the aforementioned type, the photoelectric cell in front of the copying plane to the side of the copier light beam corridor, the cell from the copier light that from the copier material or reflected by a partially transparent mirror arranged between it and the negative is illuminated. Such arrangements of the photocell are primarily with the disadvantage of a relative bulky construction associated with the entire facility and lead in particular to enlargers with a magnifying head that is adjustable over a magnifying frame often to an obstruction in the operation of the device.

There is also already known an enlarger with a device for exposure control which the photocells are arranged at the edge of the copying surface and therefore only from the edge rays the copier light beam path are taken; these marginal rays contribute to the generation of the image-important, areas of the negative image projected onto the copy surface, usually in the center of the image field does not provide and does not guarantee exposure control, which is the average density of the negative is equivalent to. The photocells can be accidentally covered by hand. Especially when copying of negatives whose density in the edge areas differs from the density in the middle of the image, This leads to overexposure or underexposure and not infrequently to unusable copies. Furthermore the size of the copies to be made cannot be varied.

Furthermore, it has also already been proposed that the photocell in the light path behind the photocell in photocopiers To arrange copy area. Here, however, the copy surface areas closer to the photocell bore proportionately more to the photocurrent of the photocell than the other copy surface areas. The photocell was therefore placed at a greater distance from the copy surface.

According to the invention it is now proposed to use photographic copiers with a photoelectric exposure control device, which controls the copying process depending on the average negative, with a To equip photocell with secondary electron multiplication as well as with an optical intermediate arrangement, which of the photocell is falling through the copying surface in the ready-to-use lighting condition of the device Supplies light in an almost uniform average density.

Exposure control device

for photographic copiers

Applicant:
ίο Fred Lander, WiI, St. Gallen (Switzerland)

Representative: Dipl.-Ing. E. Rathmann, patent attorney,
Frankfurt / M., Neue Mainzer Str. 40-42

Claimed priority:

Switzerland from April 1, 1953

Fred Lander, WiI, St. Gallen,

Max Lattmann and Robert Oberacker, Zurich (Switzerland), have been named as inventors

This ensures that the differences in the distance between the individual copying surface areas of the photocell cannot, or at least no longer have any significant effect on the exposure control. The exposure control is therefore carried out according to the average brightness for illuminating the photocell contributing image areas.

A major reason why copiers with automatic exposure control are so far have hardly been able to prevail, lies in the fact that these devices were built quite high and therefore unwieldy. According to a further proposal of the invention, the photocell is now arranged laterally behind the copying surface, and light reflecting means are provided between the copying surface and the photocell. To this This results in a particularly flat and therefore very handy arrangement. The device is particularly suitable for use as a tabletop device.

It is expedient for such a cell to be formed between the plane of the copy paper and the photoelectric cell Filter arranged that the light-attenuating effect of the individual filter areas with decreasing Distance of these areas from the photoelectric cell is greater. Preferably the light filter designed in a grid shape. However, the reflective means can also have areas of different reflective properties exhibit. For example let

£ 09 527/198

filters in the form of strips, the width of which increases with decreasing distance from the photocell place the reflective means.

When measuring the illuminance via a photocell connected downstream of the positive image section changes with the size of the format while the negative density remains the same as that determined by the photocell Measured value. So you have to, if you use known arrangements, the illuminance at Adjust the negative or the aperture by hand, which often leads to incorrect exposures when changing the format leads. According to the invention, therefore, adjustable masking tapes are provided on the copying frame coupled correction organs arranged, which influence the control device in such a way that the automatically determined exposure time is independent of the mask setting. So that the operator needs no longer have to pay attention to the size of the respective set format. Rather, it can set any image section without the possibility of incorrect exposures. In addition, on Copy frame further the control device influencing correction organs are arranged, the coupled with setting means for taking into account the paper sensitivity and permeability and for subjectively influencing the exposure time are. The correction organs advantageously influence the electrical voltage of the impact electrodes an electron multiplier built into the photoelectric cell. For example, they can be designed as potentiometers.

The setting element for subjectively influencing the exposure time is expediently elastic Provided reset elements so that it automatically returns to the starting position after release.

A particularly handy arrangement results from a housing-like design of the copy frame, which contains at least parts of the control device. The exposure control device expediently forms a structural unit with the copy frame.

Finally, according to the invention, it is also proposed that a device be moved into the image section Provide a white focus screen, which is ineffective in the non-use position. Of the The screen can be folded down at the edge of the image section and one side is white and the other Side be trained black.

An exemplary embodiment of the invention is shown in the drawing. It shows

Fig. 1 is a perspective view of an enlarging frame with a photoelectric exposure control device Depiction,

FIG. 2 shows a view similar to FIG. 1 with the cover plate broken away and partially broken away Edge parts.

3 shows a simplified basic diagram of the electrical circuit arrangement,

Fig. 4 is a full schematic of the electrical circuit arrangement.

With reference to FIGS. 1 and 2, the enlarging frame consists of a relatively low housing 10 to which a cover 12 is hinged by means of hinges 11 so that it can be opened. In the arched edge portions 13 and 14 of the cover there are slots 15 and 16, respectively, in which the alaskets 17 and 18 can be moved after the locking screws 19 and 20 have been loosened. As a result, the length 1 or the width b of an image section 21 can be changed. That part of the cover 12 which remains free with the largest possible setting of the image section is used as a translucent cover plate, e.g. B. as a matte glass sheet 1, on which a photo paper 2 (see Fig. 3, 4) is placed with the layer side up, on the layer surface in a known manner by an enlarger hung on a tripod an image of a enlarging film is projected. A plate 22, which is hinged to the mask 17 with the aid of the hinge 23, is used for focusing so that it can be in

to the image section 21 can be folded in. The side of the focus plate 22 is here, which is directed upwards in the rest position shown with solid lines, while black the other side is pure white. After the focusing has taken place, the plate 22 is in the inoperative rest position folded back, and the photo paper 2 is inserted, with the size of the desired image section is determined by the position of the masks 17 and 18. In the housing 10 under one edge of the

so cover plate 1 is built a photocell 40, which together with an amplifier system has the task of using the set image section, the photo paper and converting light falling on the translucent ground glass into a charging current for a capacitor. Depending on the size of this charging current, the capacitor will open more or less quickly charged a predetermined voltage, when reached, the light source of the enlarger is to be switched off with the aid of a control circuit arrangement, the resulting exposure time should correspond to the image brightness and the layer sensitivity.

The layer sensitivity and the light transmission of the selected photo paper can go together must be taken into account in a code number for the paper in question. Because with a high layer sensitivity the exposure time must be chosen to be shorter and a high level of light transmission Increased charging current are these two properties to be considered in the same sense. The resulting paper code can be adjusted on a setting knob 24 can be set and read on the scale 25. The device is set up by flipping the Xetz switch 26 made ready for operation, d. H. connected via the cable 27 to the alternating current network. In the plug terminals 28, the power cord 29 for the enlarger is plugged in while the connection cable 30 for the darkroom lighting is plugged into the pair of terminals 31.

By moving the setting switch 32, the light source of the enlarger can be switched on without the device for automatic exposure time control being put into operation. It it is provided that for this purpose the plate 22 is folded around its joint 23 into the image detail area and the enlarger is set to focus. Another switch 33 that is held by spring forces in the center position shown, causes when it is adjusted against the "+" position increases the exposure time compared to the position of the other Adjustment elements determined AVert, while a rotation against the "-" position shortens the Exposure time results, so that the operator has the opportunity to subjectively to the exposure time vary. A start button 34 starts the function of the device for when it is pressed briefly automatic exposure time control. The darkroom lighting is switched off and the light source of the enlarger switched on, the

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The charging capacitor is charged and switches over the white component with increasing distance from which a control arrangement in the photo cell to be described later increases. In Fig. 2, this unequal way the light source of the enlarger is illustrated by the black and white distribution of the faceplate 56 after a certain time and switches a corresponding strip distribution, at the same time the darkroom lighting is back on. The masks 17 and 18 are rigid with tapping slides that would place a grid plate 35 or 35 'of voltage divider resistors 36 or 37 in the vicinity of the photocell under the ground glass 1 coupled, whereby it can be achieved that the passage of light is weakened and, at the exposure time from the photocell, it automatically favors the passage of light for each set shape, mat size corresponds to the correct value. io In those phases of the alternating voltage, with reference to FIG. 3, it will first be explained that the photocathode 41 and the impact electrodes 42, the basic principle of the operation of the device, are negatively charged with respect to the anode 43, flows. A photocell tube 40 with built-in a current through the resistor 49 to the one Be electron multiplication system contains a photo of the charging capacitor 50, the other cathode 41 of which, a number of impact electrodes 42 and 15, is connected to the ground line 45. The one collecting electrode or anode 43. A source 44 size of this current for a certain amount of light acting for a square-wave alternating voltage, i.e. a pointed cathode 41 depends primarily on the trimmed sinusoidal voltage, is at one end on the earth line from the voltage of the impact electrodes 42 , ie line 45 and at the other end via line 46 to the one end of the secondary winding 47 of a 20 51 ^ _a b from the voltage at the terminals of the winding. A shift of the tap of the potentio feed transformer 48 is connected. The use of meters 53 in the direction of the arrow reduces this voltage; alternating voltages enable the use. It is provided that the setting knob 24 is used for voltage shaping when transformers are used. The rotation to a higher characteristic value of the photographic paper photocathode 41 is on, the other end of the winding is connected to said tapping slide in this direction of arrow 47, and each of the impact electrodes 42 is adjusted 25. An adjustment of the tap of the potentiometer 52 with an intermediate tap of this winding 47 against the restoring forces of the Febunden. The anode 43 of the photocell tube is connected to the ground line 45 via the 54 in the direction of the arrow, likewise combining a current limiting resistor 49 and a reduction in the voltage on the A winding 51, ie the capacitor 50. Between that is a reduction of the charging current for a view of the last impact electrode and the anode is 30 correct amount of light. The tapping slides of the square-wave alternating voltage of the source potentiometers 36 and 37 also cause the impedances of the resistor 49 and development in the direction of the arrows to reduce the supply voltage for the winding 51 compared to the inside of the tube. resistance are negligibly small. The primary winding 51, 35 of the correct light source is used for excitation, ie a reduction in the charging current for a bedes transformer 48. The coupling of these taps, which clamp via a multiple voltage divider arrangement to the masks 17 and 18, is such that it is also connected to the voltage source 44. the anode current is reduced if the format This voltage divider arrangement comprises four voltage is enlarged, because in this case more light voltage divider resistors 36, 37, 52 and 53, which falls on the cathode 41. Depending on the size of the charging tap of the potentiometer 36 with the mask 17 to 40 current, the capacitor 50 is more or less setting the image section width and the tap is quickly charged to a predetermined voltage, the potentiometer 37 with the mask 18 for one It should be noted that the length of the image section is coupled in a later order. The writing way of the tapping terminal of the potentiometer 52 drawn in the rest position is opened by the relay contact 57 when the device springs 54 are held in a central position and can 43 is in function. One electrode of a glow tube 58 can be moved to the anode side of the charging capacitor by means of the handle 33 from this central position. The slide of the potentiometer 53 is connected, the other electrode of which is coupled to the setting knob 24 via the primit. When setting the winding 59 of a reverse pulse transmitter 60 and a medium image format and when not activated, a negative bias voltage source 61 is connected to the ground line correction handle 33, the voltage to which the small 50 45 is connected. When a voltage of the capacitor 50 is reached before the supply winding 51 and thus the voltage of the capacitor 50 is determined, the electrodes and the photocathode of the glow tube setting 58 ignite, and a current pulse flows through the rotary knob 24. The cathode is irradiated by light up the winding 59. The control grid of the thyratron tube, which through the photo paper 2 and the light 64 is transparent via the secondary winding 62 of the transformer 1 into the photocell tube 40 55 60 and a negative bias source 63 also falls. This photocell tube 40 is connected to the earth line as much as possible. Its heating filament is heated by the voltage source 65, reducing the height of the housing, while its edge part 13 of the image section 21 is arranged, the cathode connected to the earth via the line 66, as can be seen in FIG. This can counteract it. The anode of this thyratron 64 is above the known arrangements in which the photocell 60 excitation winding of a relay 67 and a contact tube arranged in the middle under the cover plate 68 of this relay and the line 70 with which is, are significantly saved in height. Also -! - terminal of a voltage source 71 in connection, all other components are arranged along the edges of this anode is also with one of the stationary housing. But now light, the contacts of a changeover contact 69 of this relay 67 through the photocell 40 adjacent surface parts of 6g in connection. The excitation winding of another cover plate 1 falls, and light that falls through the surface parts of the cover plate removed from the photo relay 72, to which the contacts 57 and 73 belong, is to the same extent with the other fixed contact of the photocathode 41 acts, on the aforementioned switchover contact 69 and with a line at the bottom of the device there is a black and white, against the cover 74 in connection, on which the contact 73 and a flat shield plate 56 is arranged, 70 of which are the fixed contacts of the pushbutton switch 34.

are closed. The + terminal of the current source 71 is connected to the mating contacts of the switches 73 and 34. The excitation winding of a third relay 75 is connected to the positive via the holding contact 73 Terminal of the power source 71 and via the changeover switch 69 with the earth line 45 in connection. The two Fixed contacts of a start switch 33 are connected to line 74 or to the + terminal of the power source 71 connected. So if the push button switch 34 is actuated briefly, the winding is maintained the relay 72 current via the following current path:

+ Terminal of power source 71 - pushbutton switch 34-line 74-winding of relay 72-changeover contact 69 - earth.

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By energizing the relay 72, its holding contact 73 is closed, so that the relay 72 is energized remain.

The relay 75 is excited at the same time via the following current path:

+ Terminal of the power source 71 - holding contact 73 - line 74 - relay 75 - changeover contact gg _ £ _{r (} j _e

By energizing the relay 75, the changeover contact 76 is switched over, so that in place of the Darkroom lamp 78 the enlarger lamp 77 is connected to the mains voltage source ~ will. The thyratron tube 64 remains temporarily blocked because its grid is negatively biased. If then after a certain time the voltage on capacitor 50 has reached a sufficiently high limit value, ignites the glow tube 58, with a current surge flowing through the winding 59 and the battery 61 to earth. The negative bias of the glow tube 58 causes manufacturing inequalities that result in a shift the ignition voltage by a few volts can cause less large inequalities of the necessary Charging time can result. The said current pulse in the winding induces in the Winding 62 a voltage surge which makes the thyratron grid positive, so that current in the anode circuit flows. The relay 67 is energized and therefore puts its switch contacts 68 and 69 over. By the opening of the contact 68 becomes the anode of the +5 Thyratron separated from the voltage source 71, so that the thyratron goes out. By switching of the contact 69, the holding circuits for the relays 72 and 75 are interrupted so that they are de-energized. As a result, the holding contact 73 and the bridging contact 57 of the relay 72 fall into their drawn Rest position back, so that the capacitor 50 is discharged and the holding circuit for the relays 72 and 75 is definitely is interrupted. The subsequent de-excitation of the relay 67 can therefore neither re-ignition of the Thyratrons cause relays 72 and 75 to be re-excited. The ignition of the Thyratron and the de-energization of the relay 75 caused by it, its changeover contact 76 falls back on the drawn rest position back, so that the light source 77 of the enlarger is switched off again and the darkroom light 78 is turned on again.

The described arrangement of the charging capacitor 50 effectively prevents the occurrence of Auxiliary current paths for the anode current of the photocell tube 40. Only the parts framed by dash-dotted lines must be particularly well insulated, while, for example, the transmitter 48 does not open any auxiliary flow paths for the charging current. By By flipping the setting switch 32, the light source 77 of the enlarger is connected to the network connected without the means for automatic exposure time limitation being put into operation This enables the focus to be adjusted.

In the diagram according to FIG. 4, those switching elements which are designed in exactly the same way as in FIG. 3 are shown are provided with the same reference numbers, those that act analogously with a reference number larger by 100.

Above all, the various current sources are formed here. The alternating current network ~ is connected to the primary winding of the transformer 82 via the feed cable 27, the fuse 80, the mains switch 26 and the resistor 81. The primary winding 84 of the transformer 85 is likewise connected to the network via the switch 26. A center tap of the secondary winding 86 of the transformer 83 is connected to the ground line 45, and the two ends of this winding 86 are connected to ^a rectifier 89 and 90 ^{via the lines 87 and 88, respectively.} The other poles of these two rectifiers * are connected to the earth line 45 via a stabilizer glow tube 91. Under the effect of the current peak limiting resistor 81 and the rectifier 90, 89 between the line 46, which is connected to the winding 47, and the earth line 45, an alternating voltage with a peak, that is approximately a square-wave alternating voltage, arises. The four potentiometers 136, 137, 152 and 158 are used to generate the supply voltage of the winding 51, which is dependent on four parameters and have the same functions as the voltage dividers 36, 37, 52 and 58 of FIG. A partial tap 86 'of the winding 86 is connected to ground via the rectifier 92 and the parallel circuit of resistors 93 and a smoothing capacitor 94, so that the points 161 and 163 form voltage sources for negative biases of the glow tube 58 and the thyratron grid. The positive voltage source for the thyratron 64 is formed by the junction 171 of the rectifiers 89, 90 and the stabilizer tube 91, with a smoothing capacitor 70a also being arranged between the line 70 and the ground line 45. The secondary winding 95 of the transformer 85 also forms the current source for the Thyratronheizfaden and for the case designed as an alternating-current relay relays 172 and 175. The primary winding 96 of a transformer 97 bridges the resistor 81 and induced in the secondary windings 98a, 98 b correcting voltages, which the Potentiometers 136 and 137 are supplied. It can be achieved in that the winding 51 is fed with an exactly square-wave voltage, because the peak voltages at the resistor 81 are inversely transposed into the voltage divider system. Otherwise the operation of the device shown in FIG. 4 corresponds to that of FIG. At the same time, the bridging contact 57 opens, so that the voltage on the capacitor 50 begins to rise. When a predetermined voltage value is reached, the glow tube 58 ignites so that the thyratron 64 restores the device to the idle state via the relay 67. The characteristics of the voltage

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Divider resistors 136, 137 are to be chosen so that an image section extension to twice and also an image section broadening to twice the effect each have the same effect as an increase in sensitivity to double. So that the device can also be used to produce color photographic enlargements, the charging capacitor 50 can advantageously be exchanged.

Under certain circumstances, depending on the type of glow tube 58, it may be necessary to replace it after each use to connect the device to earth at least on one side by means of additional switching devices, so that this glow tube does not occur during successive actuations, for example as a result of static Charges at other voltage values of the charging capacitor ignite.

Claims (15)

Patent claims: 1. Photoelectric exposure control device for photographic copiers, depending on the ao medium negative density controls the copying process, characterized in that the device with a photocell with secondary electron multiplication and an optical intermediate arrangement is equipped, which of the photocell in the ready-to-use lighting state of the device the supplies light falling through the copying surface in an almost uniform average density. 2. Exposure control device according to claim 1, characterized in that the photocell (40) is arranged laterally behind the copying surface and light-reflecting means (56) are provided between the copying surface and the photocell (40). 3. Exposure control device according to claim 1, characterized in that between the plane of the copy paper and the photoelectric cell, a filter is arranged such that the light-attenuating effect of the individual filter areas as the distance between these areas decreases of the photoelectric cell becomes larger. 4. Exposure control device according to claim 3, characterized in that the light filter is grid-shaped is trained. 5. Exposure control device according to claims 2 and 3, characterized in that the reflective means (56) have areas of different reflective properties, 6. Exposure control device according to claim 2 to 5, characterized in that the filter in Form of strips, the width of which increases with decreasing distance from the photocell (40) on the reflective means (56) is arranged. 7. Exposure control device, in particular according to one of the preceding claims, characterized in that on the copying frame (10, 12) adjustable correction elements (36, 37) coupled to the displaceable mask bands (17, 18) are arranged which influence the control device in such a way that the automatically determined exposure time is independent of the mask position. 8. Exposure control device according to at least one of the preceding claims, characterized in that further correction elements (52, 53) influencing the control device are arranged on the copying frame (10, 12) which are provided with setting means (24, 33) for taking into account the paper sensitivity and permeability and are coupled to subjectively influence the exposure time. 9. Exposure control device according to claim 7 or 8, characterized in that the correction elements (36, 37, 52, 53) influence the electrical voltage of the impact electrodes (42) of an electron multiplier built into the photoelectric cell (40). 10. Exposure control device according to at least one of claims 7 to 9, characterized in that the correction elements (36, 37, 52, 53) are designed as potentiometers. 11. Exposure control device according to at least one of claims 8 to 10, characterized in that that the setting member (33) for subjectively influencing the exposure time with elastic Resetting elements (54) is provided. 12. Exposure control device according to at least one of the preceding claims, characterized in that that the copying frame (10, 12) is designed like a housing and at least parts the control device contains. 13. Exposure control device according to at least one of the preceding claims, characterized in that that it forms a structural unit with the copying frame. 14. Exposure control device according to at least one of the preceding claims, characterized by a white focus screen (22) which can be moved into the image section (21) and which is shown in the non-use position is ineffective. 15. Exposure control device according to at least one of the preceding claims, characterized by a screen (22) arranged so that it can be folded down at the edge of the image section, one of which Side is white and the other side is black. Considered publications: German Patent Nos. 767 288, 741 673, 179, 602 027; German patent application E 2975 IX / 57 c (published on December 4, 1952); British Patent No. 532,611; U.S. Patent No. 2,484,299. For this purpose 2 sheets of drawings © 809- 597/198 8.5 &